JP4599446B2 - Gradation control device and gradation control method - Google Patents

Description

  The present invention relates to a gradation control device and a gradation control method for an image having many moving image components.

  In recent years, television receivers that receive digital broadcasts are becoming widespread. In this television receiver, a desired packet is extracted from a transport stream and a compressed digital video signal in the packet is decoded.

  This digital video signal is compressed by the MPEG method, but when this video signal is decoded, block noise may occur. Conventionally, a coring technique has been proposed in which a pixel difference amount between fields or frames of a digital video signal is extracted, a moving image component is determined, and a noise reduction level is adaptively controlled according to the determination result. (For example, refer to Patent Document 1). In this coring control, a moving image component is detected from a video signal, and the amount of coring (noise reduction level) is changed according to the detection level. The degree of moving image is determined, for example, by detecting a histogram of difference information between frames and determining the number of pixels above a certain level.

  A technique for performing smoothing processing on a plain area of a video signal has also been proposed (see, for example, Patent Document 2). This technique is known to be effective in reducing stripes and block noise due to gradation degradation.

JP 2007-53697 A JP 2008-160440 A

  However, the technique of Patent Document 2 results in blurring of an image having a low degree of moving picture as a whole if the noise reduction effect is excessively increased.

  An object of the present invention is to provide a gradation control apparatus and a gradation control method capable of effectively reducing block noise generated in an image having a large amount of moving image components without conspicuous blurring of an image having a small amount of moving image components.

  According to the first aspect of the present invention, a coring circuit that changes the coring amount of the video signal according to the amount of motion of the video signal, a smoothing circuit that performs gradation smoothing processing on the video signal, and a video A gradation control device is provided that includes a parameter control circuit that acquires a frame difference histogram as a signal motion amount and changes an effect parameter of gradation smoothing processing in accordance with a result of weighting the histogram.

  According to a second aspect of the present invention, there is provided a gradation control method for performing gradation smoothing processing on a video signal by changing a coring amount of the video signal in accordance with a motion amount of the video signal. A gradation control method is provided in which a frame difference histogram is acquired as the amount of motion of a signal, and an effect parameter of gradation smoothing processing is changed in accordance with a result of weighting the histogram.

  In these gradation control devices and gradation control methods, a frame difference histogram is acquired as the amount of motion of the video signal, and the effect parameter of the gradation smoothing process is changed according to the result of weighting the histogram. Therefore, it is possible to set the gradation smoothing effect to increase as the amount of motion increases, and to decrease the effect of gradation smoothing as the amount of motion decreases, and there are many moving image components without conspicuous blurring of images with less moving image components Block noise generated in an image can be effectively reduced.

1 is a block diagram schematically showing a configuration of a gradation control device according to an embodiment of the present invention. It is a figure for demonstrating the operation | movement performed with the histogram acquisition circuit and weighting table shown in FIG. It is a graph which shows the example of the output characteristic of the input-output converter provided in the output of the weighting table shown in FIG. It is a graph which shows the output characteristic of the adder shown in FIG. It is a wave form diagram which shows the block noise for two gradations input into the coring circuit shown in FIG. FIG. 3 is a waveform diagram of block noise for one gradation whose level is reduced by slicing in the coring circuit shown in FIG. 1. It is a wave form diagram which shows the result of the smoothing performed by the smoothing circuit with respect to the block noise for 1 gradation obtained from the coring circuit shown in FIG. It is a wave form diagram which shows the block noise for 3 gradations further to the coring circuit shown in FIG. It is a wave form diagram which shows the block noise for two gradations which the level fell by the slice in the coring circuit shown in FIG. It is a wave form diagram which shows the result of the smoothing performed by the smoothing circuit with respect to the block noise for two gradations obtained from the coring circuit shown in FIG. It is a figure which shows the modification of the gradation control apparatus shown in FIG.

  Hereinafter, a gradation control device according to an embodiment of the present invention will be described with reference to the accompanying drawings. This gradation control device is incorporated in a television receiver, a video recorder, or a set top box that receives digital broadcasting.

  FIG. 1 schematically shows the configuration of the gradation control apparatus. In this gradation control device, the digital video signal is supplied separately, for example, as a luminance signal Y, a color signal Cb / Pb, and a color signal Cr / Pr. These signals Y, Cb / Pb, and Cr / Pr are input to the coring circuit 11 and output from the coring circuit 11 to the gradation smoothing circuit 12 as signals Y ′, Cb / Pb ′, and Cr / Pr ′. Further, the gradation smoothing circuit 12 outputs signals Y ", Cb / Pb", and Cr / Pr ". The coring circuit 11 outputs a video signal, that is, a luminance signal Y, a color signal Cb / Pb, and a color signal Cr. / Pr may be configured so as to change the coring amount of each of the / Pr, for example, as disclosed in JP 2007-53697 A. The gradation smoothing circuit 12 is a video signal from the coring circuit 11, that is, a signal. For each of Y ′, Cb / Pb ′, and Cr / Pr ′, a gradation smoothing process is performed by a method described in, for example, Japanese Patent Application Laid-Open No. 2008-160440. It may be configured to perform.

  The gradation control device further includes a frame buffer 13, a moving image component detection circuit 14, a moving image component detection circuit 15, and a subtracter 16. A video signal, for example, a luminance signal Y is input to the frame buffer 13 and the subtracter 16 in parallel. The frame buffer 13 fetches the luminance signal Y into the current frame buffer 17 as image information every frame period, holds this image information in the 1-frame delay buffer 18 with a delay of 1 frame period, and stores this image information in the subtractor 16. Output as a delayed luminance signal. The subtracter 16 outputs the difference between the delayed luminance signal and the luminance signal Y obtained from the frame buffer 13 to the moving image component detection circuit 14 as a frame difference signal. The moving image component detection circuit 14 includes a histogram acquisition circuit 19 connected to the subtracter 16, an acquisition range setting circuit 20 connected to the histogram acquisition circuit 19, and an input / output converter 21 connected to the acquisition range setting circuit 20. Including.

  In general, as the moving image component of the video signal increases, the ratio of a large value in the frame difference signal increases. Therefore, in the case of a video signal having a large number of moving image components, the histogram of the frame difference signal tends to concentrate on the larger luminance difference.

  The histogram acquisition circuit 19 acquires a histogram indicating the frame difference luminance distribution of the image from the frame difference signal for each frame period. The acquisition range setting circuit 20 sets an acquisition range for the histogram obtained from the histogram acquisition circuit 19. The input / output converter 21 calculates the sum of the frequencies (number of pixels) in the acquisition range set by the acquisition range setting circuit 20 and outputs a coring control signal corresponding to the total to the coring circuit 11. The coring circuit 11 changes the coring amount of each of the video signal, that is, the luminance signal Y, the color signal Cb / Pb, and the color signal Cr / Pr in accordance with the coring control signal.

  The histogram of the frame difference signal is also supplied to the moving image component detection circuit 15. This moving image component detection circuit 15 includes a weighting table 22 connected to the histogram acquisition circuit 19, an input / output converter 23 connected to the weighting table 22, an initial parameter setting circuit 24, an input / output converter 23, and an initial parameter setting circuit. An adder 25 connected to 24 is included. The weighting table 22 multiplies all histograms of the frame difference luminance distribution obtained from the histogram acquisition circuit 19 by weighting coefficients assigned to these histograms. The input / output converter 23 obtains the sum of the frequencies of all histograms obtained as a multiplication result from the weighting table 22 and outputs a smoothing control signal corresponding to the sum. The initial parameter setting circuit 24 sets an initial parameter (initial value) prepared as a user setting value or a manufacturer setting value as an effect parameter of the gradation smoothing process. The adder 25 gives an offset corresponding to the smoothing control signal to the effect parameter of the gradation smoothing process set by the initial parameter setting circuit 24, and outputs the resulting effect parameter to the gradation smoothing circuit 12. The gradation smoothing circuit 12 performs gradation smoothing processing on each of the video signals from the coring circuit 11, that is, the signals Y ′, Cb / Pb ′, and Cr / Pr ′, according to this effect parameter.

  Next, parameter control for gradation smoothing processing will be further described. The histogram acquisition circuit 19 acquires a histogram of the frame difference signal as shown in FIG. The weighting coefficient of the weighting table 22 is set to a monotonically increasing value as shown in FIG. 2, for example. In this case, the higher the ratio of the difference luminance value, the greater the total frequency. That is, this sum becomes larger as the moving image component of the image increases. In the input / output converter 23, the total input value is converted so that the smoothing control signal is optimized to control the gradation smoothing process.

  FIG. 3 shows an example of output characteristics of the input / output converter 23. This output characteristic maintains the output value at zero in a predetermined range where the input value is small, and increases the output value exponentially in the input value range exceeding the predetermined range. This gives an offset to the effect parameter of the gradation smoothing process. When the output of the input / output conversion output 23 is added to the output of the initial parameter setting circuit 24, the output characteristics of the adder 25 are as shown in FIG. Actually, the output of the adder 25 is output to the gradation smoothing circuit 12 as an effect parameter of the gradation smoothing process.

  That is, the effect parameter of gradation smoothing processing can be increased / decreased according to the moving image component of the video signal by weighting the histogram, and the gradation smoothing for the image signal with less moving image component by giving an offset to the effect parameter. The processing can be reliably omitted.

  Hereinafter, an example of the operation result of the gradation control device will be described in comparison with the conventional technique. Here, it is assumed that tone smoothing does not operate on a signal larger than one tone (1LSB) in consideration of blurring in a still image. First, an example that can be removed by the conventional technique will be described. When block noise corresponding to two gradations as shown in FIG. 5 is generated in the video signal and this block noise is input to the coring circuit 11, the coring circuit 11 slices the level of the block noise to generate the block noise shown in FIG. As shown in FIG. 4, the block noise is changed to one gradation with a lowered level. When this block noise is further input to the gradation smoothing circuit 12, the gradation smoothing circuit 12 performs gradation smoothing processing on the block noise to subdivide into 2 bits per gradation as shown in FIG. To block noise to be changed.

  Next, as an example that cannot be removed by the conventional technique, when block noise for three gradations is generated in the video signal and this block noise is input to the coring circuit 11, the level of the block noise in the coring circuit 11 is shown. Is changed to block noise corresponding to two gradations whose level is lowered as shown in FIG. If this block noise is further input to the gradation smoothing circuit 12, the gradation smoothing circuit 12 does not operate for signals of two or more gradations regardless of whether it is a still image or a moving image when the conventional technique is adopted. The smoothing process is not performed, and the output of the gradation smoothing circuit 12 has the same waveform as in FIG. However, with the configuration of the present embodiment described above, if the gradation smoothing circuit is set to apply a limiter with two or more gradations for still images and three or more gradations for moving images, for example, the gradation smoothing circuit 12 can prevent block noise. As shown in FIG. 10, the gradation smoothing process can be performed to change to block noise that is subdivided into two bits per gradation and shifted.

  That is, when a parameter control circuit including the frame buffer 13, the subtractor 16, the histogram acquisition circuit 19, the weighting table 22, and the input / output converter 23 is added, the block noise having a large amplitude as described above is also illustrated. By performing the tone smoothing processing shown in FIG. 10, block noise generated in an image with many moving image components can be reduced.

  In the gradation control apparatus of this embodiment, a frame difference histogram is acquired as the amount of motion of the video signal, and an offset is given to the effect parameter of the gradation smoothing process corresponding to the result of weighting this histogram. Therefore, it is possible to set the gradation smoothing effect to increase as the amount of motion increases, and to decrease the effect of gradation smoothing as the amount of motion decreases, and there are many moving image components without conspicuous blurring of images with less moving image components Block noise generated in an image can be effectively reduced.

  In addition, this invention is not limited to the above-mentioned embodiment, It can deform | transform variously.

  In the above-described embodiment, the gradation smoothing circuit 12 is disposed at the subsequent stage of the coring circuit 11, but may be disposed at the preceding stage of the coring circuit 11, for example, as in the modification shown in FIG. In this modification, the same parts as those in the above embodiment are denoted by the same reference numerals, and the description thereof is omitted. However, since the coring circuit 11 processes the video signal of the gradation smoothing processing result of the gradation smoothing circuit 12, it is necessary to make a large gain difference between the still image and the moving image. There is a possibility that the change of the picture becomes large by the transition of. In consideration of this, it is preferable that the gradation smoothing circuit 12 is arranged at the subsequent stage of the coring circuit 11.

  Incidentally, the histogram acquisition circuit 19 is provided in the moving image component detection circuit 31 for the gradation smoothing circuit 12 and is omitted in the moving image component detection circuit 32 for the coring circuit 11. The histogram acquisition circuit 19 may be provided in both the moving image component detection circuits 31 and 32. However, since the same histogram is acquired as a result, the histogram acquisition circuit 19 is replaced with the gradation smoothing circuit 12 and the coring circuit 11. However, it is possible to reduce the manufacturing cost by using both.

  DESCRIPTION OF SYMBOLS 11 ... Coring circuit, 12 ... Gradation smoothing circuit, 13 ... Frame buffer, 16 ..., Subtractor, 19 ... Histogram acquisition circuit, 22 ... Weighting table, 23 ... Input / output converter, 24 ... Initial parameter setting circuit, 25 ... adder.

Claims (8)

A coring circuit that changes the coring amount of the video signal so that the larger the motion amount of the video signal, the larger the coring amount ;
A smoothing circuit that performs gradation smoothing processing on the video signal;
A frame difference histogram is acquired as the amount of motion of the video signal, the histogram is weighted so as to include a characteristic that the frequency increases as the difference value increases, and gradation smoothing processing is performed in accordance with the sum of the weighted frequencies . A parameter control circuit for changing the effect parameter ;
A gradation control device comprising:   2. The parameter control circuit performs the weighting by using a weighting coefficient that increases a gradation smoothing effect as the motion amount increases and decreases a gradation smoothing effect as the motion amount decreases. The gradation control device described in 1.   2. The floor according to claim 1, wherein the parameter control circuit gives an offset for omitting the change of the effect parameter of the gradation smoothing process to the effect parameter of the gradation smoothing process within a predetermined range in which the amount of motion is small. Key control device.   The gradation control apparatus according to claim 1, wherein the parameter control circuit sets an initial value set by a user as an effect parameter of the gradation smoothing process.   The gradation control apparatus according to claim 1, wherein the smoothing circuit is disposed at a subsequent stage of the coring circuit.   The gradation control apparatus according to claim 1, wherein the smoothing circuit is disposed in a stage preceding the coring circuit.   2. The gradation control apparatus according to claim 1, wherein the parameter control circuit has a histogram acquisition circuit that acquires a frame difference histogram as a motion amount of a video signal in common to the smoothing circuit and the coring circuit. . A gradation control method for performing gradation smoothing processing on the video signal by changing the coring quantity of the video signal so that the larger the motion amount of the video signal is, the larger the coring amount is .
Obtain the frame difference histogram as the amount of motion of the video signal,
A gradation control method characterized by weighting the histogram so as to include a characteristic in which the frequency is increased as the difference value is higher, and changing the effect parameter of the gradation smoothing process in accordance with the sum of the weighted frequencies. .

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